Abstract
Abstract. Solar trackers are often used by spectrometers to measure atmospheric trace gas concentrations using direct sun spectroscopy. The ideal solar tracker should be sufficiently accurate, highly reliable, and with a longevity that exceeds the lifetime of the spectrometer that it serves. It should also be affordable, easy to use, and not too complex should maintenance be required. In this paper we present a design that fulfils these requirements using some simple innovations. Our altitude–azimuth design features a custom coaxial power transformer, enabling continuous 360∘ azimuth rotation. This increases reliability and avoids the need to reverse the tracker each day. In polar regions, measurements can continue uninterrupted through the summer polar day. Tracking accuracy is enhanced using a simple optical feedback technique that adjusts error offset variables while monitoring the edges of a focused solar image with four photodiodes. Control electronics are modular, and our software is written in Python, running as a web server on a recycled laptop with a Linux operating system. Over a period of 11 years we have assembled four such trackers. These are in use at Lauder (45∘ S), New Zealand, and Arrival Heights (78∘ S), Antarctica, achieving a history of good reliability even in polar conditions. Tracker accuracy is analysed regularly and can routinely produce a pointing accuracy of 0.02∘.
Highlights
Altitude–azimuth (ALT-AZ) solar trackers are in widespread use within the atmospheric research community
At low solar elevations, the error in assumed absorption path length, or air mass, is significant if the tracker is pointing too high or too low with respect to the solar centre (Reichert et al, 2015). Another type of error occurs if the tracker pointing is unstable in any direction, causing the signal intensity at the spectrometer entrance optics to vary during the observation period, resulting in analysis inaccuracy for an Fourier Transform InfraRed spectrometers (FTIRs) measurement (Keppel-Aleks et al, 2007)
The circular image can be outlined in ink and any deviations can be assessed in terms of relative movement of the solar diameter
Summary
Altitude–azimuth (ALT-AZ) solar trackers are in widespread use within the atmospheric research community. At low solar elevations, the error in assumed absorption path length, or air mass, is significant if the tracker is pointing too high or too low with respect to the solar centre (Reichert et al, 2015). Another type of error occurs if the tracker pointing is unstable in any direction, causing the signal intensity at the spectrometer entrance optics to vary during the observation period, resulting in analysis inaccuracy for an FTIR measurement (Keppel-Aleks et al, 2007)
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